// Copyright (c) HashiCorp, Inc. // SPDX-License-Identifier: MPL-2.0 package nomad import ( "context" "crypto/tls" "crypto/x509" "encoding/json" "errors" "fmt" "net" "net/rpc" "os" "path/filepath" "sort" "strconv" "strings" "sync" "sync/atomic" "time" "github.com/armon/go-metrics" consulapi "github.com/hashicorp/consul/api" log "github.com/hashicorp/go-hclog" multierror "github.com/hashicorp/go-multierror" "github.com/hashicorp/nomad/acl" "github.com/hashicorp/raft" autopilot "github.com/hashicorp/raft-autopilot" raftboltdb "github.com/hashicorp/raft-boltdb/v2" "github.com/hashicorp/serf/serf" "go.etcd.io/bbolt" "github.com/hashicorp/nomad/command/agent/consul" "github.com/hashicorp/nomad/helper" "github.com/hashicorp/nomad/helper/codec" "github.com/hashicorp/nomad/helper/pool" "github.com/hashicorp/nomad/helper/stats" "github.com/hashicorp/nomad/helper/tlsutil" "github.com/hashicorp/nomad/lib/auth/oidc" "github.com/hashicorp/nomad/nomad/deploymentwatcher" "github.com/hashicorp/nomad/nomad/drainer" "github.com/hashicorp/nomad/nomad/state" "github.com/hashicorp/nomad/nomad/structs" "github.com/hashicorp/nomad/nomad/structs/config" "github.com/hashicorp/nomad/nomad/volumewatcher" "github.com/hashicorp/nomad/scheduler" ) const ( // datacenterQueryLimit sets the max number of DCs that a Nomad // Server will query to find bootstrap_expect servers. datacenterQueryLimit = 25 // maxStaleLeadership is the maximum time we will permit this Nomad // Server to go without seeing a valid Raft leader. maxStaleLeadership = 15 * time.Second // peersPollInterval is used as the polling interval between attempts // to query Consul for Nomad Servers. peersPollInterval = 45 * time.Second // peersPollJitter is used to provide a slight amount of variance to // the retry interval when querying Consul Servers peersPollJitterFactor = 2 raftState = "raft/" serfSnapshot = "serf/snapshot" snapshotsRetained = 2 // serverRPCCache controls how long we keep an idle connection open to a server serverRPCCache = 2 * time.Minute // serverMaxStreams controls how many idle streams we keep open to a server serverMaxStreams = 64 // raftLogCacheSize is the maximum number of logs to cache in-memory. // This is used to reduce disk I/O for the recently committed entries. raftLogCacheSize = 512 // raftRemoveGracePeriod is how long we wait to allow a RemovePeer // to replicate to gracefully leave the cluster. raftRemoveGracePeriod = 5 * time.Second // defaultConsulDiscoveryInterval is how often to poll Consul for new // servers if there is no leader. defaultConsulDiscoveryInterval time.Duration = 3 * time.Second // defaultConsulDiscoveryIntervalRetry is how often to poll Consul for // new servers if there is no leader and the last Consul query failed. defaultConsulDiscoveryIntervalRetry time.Duration = 9 * time.Second // aclCacheSize is the number of ACL objects to keep cached. ACLs have a parsing and // construction cost, so we keep the hot objects cached to reduce the ACL token resolution time. aclCacheSize = 512 ) // Server is Nomad server which manages the job queues, // schedulers, and notification bus for agents. type Server struct { config *Config logger log.InterceptLogger // Connection pool to other Nomad servers connPool *pool.ConnPool // The raft instance is used among Nomad nodes within the // region to protect operations that require strong consistency raft *raft.Raft raftLayer *RaftLayer raftStore *raftboltdb.BoltStore raftInmem *raft.InmemStore raftTransport *raft.NetworkTransport // reassertLeaderCh is used to signal that the leader loop must // re-establish leadership. // // This might be relevant in snapshot restores, where leader in-memory // state changed significantly such that leader state (e.g. periodic // jobs, eval brokers) need to be recomputed. reassertLeaderCh chan chan error // autopilot is the Autopilot instance for this server. autopilot *autopilot.Autopilot // fsm is the state machine used with Raft fsm *nomadFSM // rpcListener is used to listen for incoming connections rpcListener net.Listener listenerCh chan struct{} // tlsWrap is used to wrap outbound connections using TLS. It should be // accessed using the lock. tlsWrap tlsutil.RegionWrapper tlsWrapLock sync.RWMutex // TODO(alex,hclog): Can I move more into the handler? // rpcHandler is used to serve and handle RPCs *rpcHandler // rpcServer is the static RPC server that is used by the local agent. rpcServer *rpc.Server // clientRpcAdvertise is the advertised RPC address for Nomad clients to connect // to this server clientRpcAdvertise net.Addr // serverRpcAdvertise is the advertised RPC address for Nomad servers to connect // to this server serverRpcAdvertise net.Addr // rpcTLS is the TLS config for incoming TLS requests rpcTLS *tls.Config rpcCancel context.CancelFunc // streamingRpcs is the registry holding our streaming RPC handlers. streamingRpcs *structs.StreamingRpcRegistry // nodeConns is the set of multiplexed node connections we have keyed by // NodeID nodeConns map[string][]*nodeConnState nodeConnsLock sync.RWMutex // peers is used to track the known Nomad servers. This is // used for region forwarding and clustering. peers map[string][]*serverParts localPeers map[raft.ServerAddress]*serverParts peerLock sync.RWMutex // serf is the Serf cluster containing only Nomad // servers. This is used for multi-region federation // and automatic clustering within regions. serf *serf.Serf // bootstrapped indicates if Server has bootstrapped or not. bootstrapped *atomic.Bool // reconcileCh is used to pass events from the serf handler // into the leader manager. Mostly used to handle when servers // join/leave from the region. reconcileCh chan serf.Member // used to track when the server is ready to serve consistent reads, updated atomically readyForConsistentReads *atomic.Bool // eventCh is used to receive events from the serf cluster eventCh chan serf.Event // BlockedEvals is used to manage evaluations that are blocked on node // capacity changes. blockedEvals *BlockedEvals // evalBroker is used to manage the in-progress evaluations // that are waiting to be brokered to a sub-scheduler evalBroker *EvalBroker // brokerLock is used to synchronise the alteration of the blockedEvals and // evalBroker enabled state. These two subsystems change state when // leadership changes or when the user modifies the setting via the // operator scheduler configuration. This lock allows these actions to be // performed safely, without potential for user interactions and leadership // transitions to collide and create inconsistent state. brokerLock sync.Mutex // reapCancelableEvalsCh is used to signal the cancelable evals reaper to wake up reapCancelableEvalsCh chan struct{} // deploymentWatcher is used to watch deployments and their allocations and // make the required calls to continue to transition the deployment. deploymentWatcher *deploymentwatcher.Watcher // nodeDrainer is used to drain allocations from nodes. nodeDrainer *drainer.NodeDrainer // volumeWatcher is used to release volume claims volumeWatcher *volumewatcher.Watcher // volumeControllerFutures is a map of plugin IDs to pending controller RPCs. If // no RPC is pending for a given plugin, this may be nil. volumeControllerFutures map[string]context.Context // volumeControllerLock synchronizes access controllerFutures map volumeControllerLock sync.Mutex // keyringReplicator is used to replicate root encryption keys from the // leader keyringReplicator *KeyringReplicator // encrypter is the root keyring for encrypting variables and signing // workload identities encrypter *Encrypter // periodicDispatcher is used to track and create evaluations for periodic jobs. periodicDispatcher *PeriodicDispatch // planner is used to mange the submitted allocation plans that are waiting // to be accessed by the leader *planner // nodeHeartbeater is used to track expiration times of node heartbeats. If it // detects an expired node, the node status is updated to be 'down'. *nodeHeartbeater // consulCatalog is used for discovering other Nomad Servers via Consul consulCatalog consul.CatalogAPI // consulConfigEntries is used for managing Consul Configuration Entries. consulConfigEntries ConsulConfigsAPI // consulACLs is used for managing Consul Service Identity tokens. consulACLs ConsulACLsAPI // vault is the client for communicating with Vault. vault VaultClient // Worker used for processing workers []*Worker workerLock sync.RWMutex workerConfigLock sync.RWMutex workersEventCh chan interface{} // aclCache is used to maintain the parsed ACL objects aclCache *structs.ACLCache[*acl.ACL] // oidcProviderCache maintains a cache of OIDC providers. This is useful as // the provider performs background HTTP requests. When the Nomad server is // shutting down, the oidcProviderCache.Shutdown() function must be called. oidcProviderCache *oidc.ProviderCache // leaderAcl is the management ACL token that is valid when resolved by the // current leader. leaderAcl string leaderAclLock sync.Mutex // clusterIDLock ensures the server does not try to concurrently establish // a cluster ID, racing against itself in calls of ClusterID clusterIDLock sync.Mutex // statsFetcher is used by autopilot to check the status of the other // Nomad router. statsFetcher *StatsFetcher // EnterpriseState is used to fill in state for Pro/Ent builds EnterpriseState left bool shutdown bool shutdownLock sync.Mutex shutdownCtx context.Context shutdownCancel context.CancelFunc shutdownCh <-chan struct{} } // NewServer is used to construct a new Nomad server from the // configuration, potentially returning an error func NewServer(config *Config, consulCatalog consul.CatalogAPI, consulConfigEntries consul.ConfigAPI, consulACLs consul.ACLsAPI) (*Server, error) { // Create an eval broker evalBroker, err := NewEvalBroker( config.EvalNackTimeout, config.EvalNackInitialReenqueueDelay, config.EvalNackSubsequentReenqueueDelay, config.EvalDeliveryLimit) if err != nil { return nil, err } // Configure TLS tlsConf, err := tlsutil.NewTLSConfiguration(config.TLSConfig, true, true) if err != nil { return nil, err } incomingTLS, tlsWrap, err := getTLSConf(config.TLSConfig.EnableRPC, tlsConf, config.Region) if err != nil { return nil, err } // Create the ACL object cache aclCache := structs.NewACLCache[*acl.ACL](aclCacheSize) // Create the logger logger := config.Logger.ResetNamedIntercept("nomad") // Validate enterprise license before anything stateful happens if err = config.LicenseConfig.Validate(); err != nil { return nil, err } // Create the server s := &Server{ config: config, consulCatalog: consulCatalog, connPool: pool.NewPool(logger, serverRPCCache, serverMaxStreams, tlsWrap), logger: logger, tlsWrap: tlsWrap, rpcServer: rpc.NewServer(), streamingRpcs: structs.NewStreamingRpcRegistry(), nodeConns: make(map[string][]*nodeConnState), peers: make(map[string][]*serverParts), localPeers: make(map[raft.ServerAddress]*serverParts), bootstrapped: &atomic.Bool{}, reassertLeaderCh: make(chan chan error), reconcileCh: make(chan serf.Member, 32), readyForConsistentReads: &atomic.Bool{}, eventCh: make(chan serf.Event, 256), evalBroker: evalBroker, reapCancelableEvalsCh: make(chan struct{}), blockedEvals: NewBlockedEvals(evalBroker, logger), rpcTLS: incomingTLS, aclCache: aclCache, workersEventCh: make(chan interface{}, 1), } s.shutdownCtx, s.shutdownCancel = context.WithCancel(context.Background()) s.shutdownCh = s.shutdownCtx.Done() // Create the RPC handler s.rpcHandler = newRpcHandler(s) // Create the planner planner, err := newPlanner(s) if err != nil { return nil, err } s.planner = planner // Create the node heartbeater s.nodeHeartbeater = newNodeHeartbeater(s) // Create the periodic dispatcher for launching periodic jobs. s.periodicDispatcher = NewPeriodicDispatch(s.logger, s) // Initialize the stats fetcher that autopilot will use. s.statsFetcher = NewStatsFetcher(s.logger, s.connPool, s.config.Region) // Setup Consul (more) s.setupConsul(consulConfigEntries, consulACLs) // Setup Vault if err := s.setupVaultClient(); err != nil { s.Shutdown() s.logger.Error("failed to setup Vault client", "error", err) return nil, fmt.Errorf("Failed to setup Vault client: %v", err) } // Set up the keyring keystorePath := filepath.Join(s.config.DataDir, "keystore") if s.config.DevMode && s.config.DataDir == "" { keystorePath, err = os.MkdirTemp("", "nomad-keystore") if err != nil { return nil, fmt.Errorf("Failed to create keystore tempdir") } } encrypter, err := NewEncrypter(s, keystorePath) if err != nil { return nil, err } s.encrypter = encrypter // Set up the OIDC provider cache. This is needed by the setupRPC, but must // be done separately so that the server can stop all background processes // when it shuts down itself. s.oidcProviderCache = oidc.NewProviderCache() // Initialize the RPC layer if err := s.setupRPC(tlsWrap); err != nil { s.Shutdown() s.logger.Error("failed to start RPC layer", "error", err) return nil, fmt.Errorf("Failed to start RPC layer: %v", err) } // Initialize the Raft server if err := s.setupRaft(); err != nil { s.Shutdown() s.logger.Error("failed to start Raft", "error", err) return nil, fmt.Errorf("Failed to start Raft: %v", err) } // Initialize the wan Serf s.serf, err = s.setupSerf(config.SerfConfig, s.eventCh, serfSnapshot) if err != nil { s.Shutdown() s.logger.Error("failed to start serf WAN", "error", err) return nil, fmt.Errorf("Failed to start serf: %v", err) } // Initialize the scheduling workers if err := s.setupWorkers(s.shutdownCtx); err != nil { s.Shutdown() s.logger.Error("failed to start workers", "error", err) return nil, fmt.Errorf("Failed to start workers: %v", err) } // Setup the Consul syncer if err := s.setupConsulSyncer(); err != nil { s.logger.Error("failed to create server consul syncer", "error", err) return nil, fmt.Errorf("failed to create server Consul syncer: %v", err) } // Setup the deployment watcher. if err := s.setupDeploymentWatcher(); err != nil { s.logger.Error("failed to create deployment watcher", "error", err) return nil, fmt.Errorf("failed to create deployment watcher: %v", err) } // Setup the volume watcher if err := s.setupVolumeWatcher(); err != nil { s.logger.Error("failed to create volume watcher", "error", err) return nil, fmt.Errorf("failed to create volume watcher: %v", err) } s.volumeControllerFutures = map[string]context.Context{} // Start the eval broker notification system so any subscribers can get // updates when the processes SetEnabled is triggered. go s.evalBroker.enabledNotifier.Run(s.shutdownCh) // Setup the node drainer. s.setupNodeDrainer() // Setup the enterprise state if err := s.setupEnterprise(config); err != nil { return nil, err } // Monitor leadership changes go s.monitorLeadership() // Start ingesting events for Serf go s.serfEventHandler() // start the RPC listener for the server s.startRPCListener() // Emit metrics for the eval broker go evalBroker.EmitStats(time.Second, s.shutdownCh) // Emit metrics for the plan queue go s.planQueue.EmitStats(time.Second, s.shutdownCh) // Emit metrics for the planner's bad node tracker. go s.planner.badNodeTracker.EmitStats(time.Second, s.shutdownCh) // Emit metrics for the blocked eval tracker. go s.blockedEvals.EmitStats(time.Second, s.shutdownCh) // Emit metrics for the Vault client. go s.vault.EmitStats(time.Second, s.shutdownCh) // Emit metrics go s.heartbeatStats() // Emit raft and state store metrics go s.EmitRaftStats(10*time.Second, s.shutdownCh) // Start enterprise background workers s.startEnterpriseBackground() // Enable the keyring replicator on servers; the replicator has to // be created before the RPC server and FSM but needs them to // exist before it can start. s.keyringReplicator = NewKeyringReplicator(s, encrypter) // Done return s, nil } // startRPCListener starts the server's the RPC listener func (s *Server) startRPCListener() { ctx, cancel := context.WithCancel(context.Background()) s.rpcCancel = cancel go s.listen(ctx) } // createRPCListener creates the server's RPC listener func (s *Server) createRPCListener() (*net.TCPListener, error) { s.listenerCh = make(chan struct{}) listener, err := net.ListenTCP("tcp", s.config.RPCAddr) if err != nil { s.logger.Error("failed to initialize TLS listener", "error", err) return listener, err } s.rpcListener = listener return listener, nil } // getTLSConf gets the server's TLS configuration based on the config supplied // by the operator func getTLSConf(enableRPC bool, tlsConf *tlsutil.Config, region string) (*tls.Config, tlsutil.RegionWrapper, error) { var tlsWrap tlsutil.RegionWrapper var incomingTLS *tls.Config if !enableRPC { return incomingTLS, tlsWrap, nil } tlsWrap, err := tlsConf.OutgoingTLSWrapper() if err != nil { return nil, nil, err } itls, err := tlsConf.IncomingTLSConfig() if err != nil { return nil, nil, err } if tlsConf.VerifyServerHostname { incomingTLS = itls.Clone() incomingTLS.VerifyPeerCertificate = rpcNameAndRegionValidator(region) } else { incomingTLS = itls } return incomingTLS, tlsWrap, nil } // implements signature of tls.Config.VerifyPeerCertificate which is called // after the certs have been verified. We'll ignore the raw certs and only // check the verified certs. func rpcNameAndRegionValidator(region string) func([][]byte, [][]*x509.Certificate) error { return func(_ [][]byte, certificates [][]*x509.Certificate) error { if len(certificates) > 0 && len(certificates[0]) > 0 { cert := certificates[0][0] for _, dnsName := range cert.DNSNames { if validateRPCRegionPeer(dnsName, region) { return nil } } if validateRPCRegionPeer(cert.Subject.CommonName, region) { return nil } } return errors.New("invalid role or region for certificate") } } func validateRPCRegionPeer(name, region string) bool { parts := strings.Split(name, ".") if len(parts) < 3 { // Invalid SAN return false } if parts[len(parts)-1] != "nomad" { // Incorrect service return false } if parts[0] == "client" { // Clients may only connect to servers in their region return name == "client."+region+".nomad" } // Servers may connect to any Nomad RPC service for federation. return parts[0] == "server" } // reloadTLSConnections updates a server's TLS configuration and reloads RPC // connections. func (s *Server) reloadTLSConnections(newTLSConfig *config.TLSConfig) error { s.logger.Info("reloading server connections due to configuration changes") // Check if we can reload the RPC listener if s.rpcListener == nil || s.rpcCancel == nil { s.logger.Warn("unable to reload configuration due to uninitialized rpc listener") return fmt.Errorf("can't reload uninitialized RPC listener") } tlsConf, err := tlsutil.NewTLSConfiguration(newTLSConfig, true, true) if err != nil { s.logger.Error("unable to create TLS configuration", "error", err) return err } incomingTLS, tlsWrap, err := getTLSConf(newTLSConfig.EnableRPC, tlsConf, s.config.Region) if err != nil { s.logger.Error("unable to reset TLS context", "error", err) return err } // Store the new tls wrapper. s.tlsWrapLock.Lock() s.tlsWrap = tlsWrap s.tlsWrapLock.Unlock() // Keeping configuration in sync is important for other places that require // access to config information, such as rpc.go, where we decide on what kind // of network connections to accept depending on the server configuration s.config.TLSConfig = newTLSConfig // Kill any old listeners s.rpcCancel() s.rpcTLS = incomingTLS s.connPool.ReloadTLS(tlsWrap) if err := s.rpcListener.Close(); err != nil { s.logger.Error("unable to close rpc listener", "error", err) return err } // Wait for the old listener to exit <-s.listenerCh // Create the new listener with the update TLS config listener, err := s.createRPCListener() if err != nil { listener.Close() return err } // Start the new RPC listener s.startRPCListener() // Close and reload existing Raft connections wrapper := tlsutil.RegionSpecificWrapper(s.config.Region, tlsWrap) s.raftLayer.ReloadTLS(wrapper) s.raftTransport.CloseStreams() s.logger.Debug("finished reloading server connections") return nil } // Shutdown is used to shutdown the server func (s *Server) Shutdown() error { s.logger.Info("shutting down server") s.shutdownLock.Lock() defer s.shutdownLock.Unlock() if s.shutdown { return nil } s.shutdown = true s.shutdownCancel() if s.serf != nil { s.serf.Shutdown() } if s.raft != nil { s.raftTransport.Close() s.raftLayer.Close() future := s.raft.Shutdown() if err := future.Error(); err != nil { s.logger.Warn("error shutting down raft", "error", err) } if s.raftStore != nil { s.raftStore.Close() } } // Shutdown the RPC listener if s.rpcListener != nil { s.rpcListener.Close() } // Close the connection pool s.connPool.Shutdown() // Close the fsm if s.fsm != nil { s.fsm.Close() } // Stop Vault token renewal and revocations if s.vault != nil { s.vault.Stop() } // Stop the Consul ACLs token revocations s.consulACLs.Stop() // Stop being able to set Configuration Entries s.consulConfigEntries.Stop() // Shutdown the OIDC provider cache which contains background resources and // processes. if s.oidcProviderCache != nil { s.oidcProviderCache.Shutdown() } return nil } // IsShutdown checks if the server is shutdown func (s *Server) IsShutdown() bool { select { case <-s.shutdownCh: return true default: return false } } // Leave is used to prepare for a graceful shutdown of the server func (s *Server) Leave() error { s.logger.Info("server starting leave") s.left = true // Check the number of known peers numPeers, err := s.numPeers() if err != nil { s.logger.Error("failed to check raft peers during leave", "error", err) return err } addr := s.raftTransport.LocalAddr() // If we are the current leader, and we have any other peers (cluster has multiple // servers), we should do a RemovePeer to safely reduce the quorum size. If we are // not the leader, then we should issue our leave intention and wait to be removed // for some sane period of time. isLeader := s.IsLeader() if isLeader && numPeers > 1 { minRaftProtocol, err := s.MinRaftProtocol() if err != nil { return err } if minRaftProtocol >= 2 && s.config.RaftConfig.ProtocolVersion >= 3 { future := s.raft.RemoveServer(raft.ServerID(s.config.NodeID), 0, 0) if err := future.Error(); err != nil { s.logger.Error("failed to remove ourself as raft peer", "error", err) } } else { future := s.raft.RemovePeer(addr) if err := future.Error(); err != nil { s.logger.Error("failed to remove ourself as raft peer", "error", err) } } } // Leave the gossip pool if s.serf != nil { if err := s.serf.Leave(); err != nil { s.logger.Error("failed to leave Serf cluster", "error", err) } } // If we were not leader, wait to be safely removed from the cluster. // We must wait to allow the raft replication to take place, otherwise // an immediate shutdown could cause a loss of quorum. if !isLeader { left := false limit := time.Now().Add(raftRemoveGracePeriod) for !left && time.Now().Before(limit) { // Sleep a while before we check. time.Sleep(50 * time.Millisecond) // Get the latest configuration. future := s.raft.GetConfiguration() if err := future.Error(); err != nil { s.logger.Error("failed to get raft configuration", "error", err) break } // See if we are no longer included. left = true for _, server := range future.Configuration().Servers { if server.Address == addr { left = false break } } } // TODO (alexdadgar) With the old Raft library we used to force the // peers set to empty when a graceful leave occurred. This would // keep voting spam down if the server was restarted, but it was // dangerous because the peers was inconsistent with the logs and // snapshots, so it wasn't really safe in all cases for the server // to become leader. This is now safe, but the log spam is noisy. // The next new version of the library will have a "you are not a // peer stop it" behavior that should address this. We will have // to evaluate during the RC period if this interim situation is // not too confusing for operators. // TODO (alexdadgar) When we take a later new version of the Raft // library it won't try to complete replication, so this peer // may not realize that it has been removed. Need to revisit this // and the warning here. if !left { s.logger.Warn("failed to leave raft configuration gracefully, timeout") } } return nil } // Reload handles a config reload specific to server-only configuration. Not // all config fields can handle a reload. func (s *Server) Reload(newConfig *Config) error { if newConfig == nil { return fmt.Errorf("Reload given a nil config") } var mErr multierror.Error // Handle the Vault reload. Vault should never be nil but just guard. if s.vault != nil { if err := s.vault.SetConfig(newConfig.VaultConfig); err != nil { _ = multierror.Append(&mErr, err) } } shouldReloadTLS, err := tlsutil.ShouldReloadRPCConnections(s.config.TLSConfig, newConfig.TLSConfig) if err != nil { s.logger.Error("error checking whether to reload TLS configuration", "error", err) } if shouldReloadTLS { if err := s.reloadTLSConnections(newConfig.TLSConfig); err != nil { s.logger.Error("error reloading server TLS configuration", "error", err) _ = multierror.Append(&mErr, err) } } if newConfig.LicenseConfig.LicenseEnvBytes != "" || newConfig.LicenseConfig.LicensePath != "" { if err = s.EnterpriseState.ReloadLicense(newConfig); err != nil { s.logger.Error("error reloading license", "error", err) _ = multierror.Append(&mErr, err) } } // Because this is a new configuration, we extract the worker pool arguments without acquiring a lock workerPoolArgs := getSchedulerWorkerPoolArgsFromConfigLocked(newConfig) if reload, newVals := shouldReloadSchedulers(s, workerPoolArgs); reload { if newVals.IsValid() { reloadSchedulers(s, newVals) } reloadSchedulers(s, newVals) } raftRC := raft.ReloadableConfig{ TrailingLogs: newConfig.RaftConfig.TrailingLogs, SnapshotInterval: newConfig.RaftConfig.SnapshotInterval, SnapshotThreshold: newConfig.RaftConfig.SnapshotThreshold, HeartbeatTimeout: newConfig.RaftConfig.HeartbeatTimeout, ElectionTimeout: newConfig.RaftConfig.ElectionTimeout, } if err := s.raft.ReloadConfig(raftRC); err != nil { multierror.Append(&mErr, err) } return mErr.ErrorOrNil() } // setupBootstrapHandler() creates the closure necessary to support a Consul // fallback handler. func (s *Server) setupBootstrapHandler() error { // peersTimeout is used to indicate to the Consul Syncer that the // current Nomad Server has a stale peer set. peersTimeout will time // out if the Consul Syncer bootstrapFn has not observed a Raft // leader in maxStaleLeadership. If peersTimeout has been triggered, // the Consul Syncer will begin querying Consul for other Nomad // Servers. // // NOTE: time.Timer is used vs time.Time in order to handle clock // drift because time.Timer is implemented as a monotonic clock. var peersTimeout *time.Timer = time.NewTimer(0) // consulQueryCount is the number of times the bootstrapFn has been // called, regardless of success. var consulQueryCount uint64 // leadershipTimedOut is a helper method that returns true if the // peersTimeout timer has expired. leadershipTimedOut := func() bool { select { case <-peersTimeout.C: return true default: return false } } // The bootstrapFn callback handler is used to periodically poll // Consul to look up the Nomad Servers in Consul. In the event the // server has been brought up without a `retry-join` configuration // and this Server is partitioned from the rest of the cluster, // periodically poll Consul to reattach this Server to other servers // in the same region and automatically reform a quorum (assuming the // correct number of servers required for quorum are present). bootstrapFn := func() error { // If there is a raft leader, do nothing if s.raft.Leader() != "" { peersTimeout.Reset(maxStaleLeadership) return nil } // (ab)use serf.go's behavior of setting BootstrapExpect to // zero if we have bootstrapped. If we have bootstrapped bootstrapExpect := s.config.BootstrapExpect if bootstrapExpect == 0 { // This Nomad Server has been bootstrapped. Rely on // the peersTimeout firing as a guard to prevent // aggressive querying of Consul. if !leadershipTimedOut() { return nil } } else { if consulQueryCount > 0 && !leadershipTimedOut() { return nil } // This Nomad Server has not been bootstrapped, reach // out to Consul if our peer list is less than // `bootstrap_expect`. raftPeers, err := s.numPeers() if err != nil { peersTimeout.Reset(peersPollInterval + helper.RandomStagger(peersPollInterval/peersPollJitterFactor)) return nil } // The necessary number of Nomad Servers required for // quorum has been reached, we do not need to poll // Consul. Let the normal timeout-based strategy // take over. if raftPeers >= bootstrapExpect { peersTimeout.Reset(peersPollInterval + helper.RandomStagger(peersPollInterval/peersPollJitterFactor)) return nil } } consulQueryCount++ s.logger.Debug("lost contact with Nomad quorum, falling back to Consul for server list") dcs, err := s.consulCatalog.Datacenters() if err != nil { peersTimeout.Reset(peersPollInterval + helper.RandomStagger(peersPollInterval/peersPollJitterFactor)) return fmt.Errorf("server.nomad: unable to query Consul datacenters: %v", err) } if len(dcs) > 2 { // Query the local DC first, then shuffle the // remaining DCs. If additional calls to bootstrapFn // are necessary, this Nomad Server will eventually // walk all datacenter until it finds enough hosts to // form a quorum. shuffleStrings(dcs[1:]) dcs = dcs[0:helper.Min(len(dcs), datacenterQueryLimit)] } nomadServerServiceName := s.config.ConsulConfig.ServerServiceName var mErr multierror.Error const defaultMaxNumNomadServers = 8 nomadServerServices := make([]string, 0, defaultMaxNumNomadServers) localNode := s.serf.Memberlist().LocalNode() for _, dc := range dcs { consulOpts := &consulapi.QueryOptions{ AllowStale: true, Datacenter: dc, Near: "_agent", WaitTime: consul.DefaultQueryWaitDuration, } consulServices, _, err := s.consulCatalog.Service(nomadServerServiceName, consul.ServiceTagSerf, consulOpts) if err != nil { err := fmt.Errorf("failed to query service %q in Consul datacenter %q: %v", nomadServerServiceName, dc, err) s.logger.Warn("failed to query Nomad service in Consul datacenter", "service_name", nomadServerServiceName, "dc", dc, "error", err) mErr.Errors = append(mErr.Errors, err) continue } for _, cs := range consulServices { port := strconv.FormatInt(int64(cs.ServicePort), 10) addr := cs.ServiceAddress if addr == "" { addr = cs.Address } if localNode.Addr.String() == addr && int(localNode.Port) == cs.ServicePort { continue } serverAddr := net.JoinHostPort(addr, port) nomadServerServices = append(nomadServerServices, serverAddr) } } if len(nomadServerServices) == 0 { if len(mErr.Errors) > 0 { peersTimeout.Reset(peersPollInterval + helper.RandomStagger(peersPollInterval/peersPollJitterFactor)) return mErr.ErrorOrNil() } // Log the error and return nil so future handlers // can attempt to register the `nomad` service. pollInterval := peersPollInterval + helper.RandomStagger(peersPollInterval/peersPollJitterFactor) s.logger.Trace("no Nomad Servers advertising Nomad service in Consul datacenters", "service_name", nomadServerServiceName, "datacenters", dcs, "retry", pollInterval) peersTimeout.Reset(pollInterval) return nil } numServersContacted, err := s.Join(nomadServerServices) if err != nil { peersTimeout.Reset(peersPollInterval + helper.RandomStagger(peersPollInterval/peersPollJitterFactor)) return fmt.Errorf("contacted %d Nomad Servers: %v", numServersContacted, err) } peersTimeout.Reset(maxStaleLeadership) s.logger.Info("successfully contacted Nomad servers", "num_servers", numServersContacted) return nil } // Hacky replacement for old ConsulSyncer Periodic Handler. go func() { lastOk := true sync := time.NewTimer(0) for { select { case <-sync.C: d := defaultConsulDiscoveryInterval if err := bootstrapFn(); err != nil { // Only log if it worked last time if lastOk { lastOk = false s.logger.Error("error looking up Nomad servers in Consul", "error", err) } d = defaultConsulDiscoveryIntervalRetry } sync.Reset(d) case <-s.shutdownCh: return } } }() return nil } // setupConsulSyncer creates Server-mode consul.Syncer which periodically // executes callbacks on a fixed interval. func (s *Server) setupConsulSyncer() error { if s.config.ConsulConfig.ServerAutoJoin != nil && *s.config.ConsulConfig.ServerAutoJoin { if err := s.setupBootstrapHandler(); err != nil { return err } } return nil } // setupDeploymentWatcher creates a deployment watcher that consumes the RPC // endpoints for state information and makes transitions via Raft through a // shim that provides the appropriate methods. func (s *Server) setupDeploymentWatcher() error { // Create the raft shim type to restrict the set of raft methods that can be // made raftShim := &deploymentWatcherRaftShim{ apply: s.raftApply, } // Create the deployment watcher s.deploymentWatcher = deploymentwatcher.NewDeploymentsWatcher( s.logger, raftShim, NewDeploymentEndpoint(s, nil), NewJobEndpoints(s, nil), s.config.DeploymentQueryRateLimit, deploymentwatcher.CrossDeploymentUpdateBatchDuration, ) return nil } // setupVolumeWatcher creates a volume watcher that sends CSI RPCs func (s *Server) setupVolumeWatcher() error { s.volumeWatcher = volumewatcher.NewVolumesWatcher( s.logger, NewCSIVolumeEndpoint(s, nil), s.getLeaderAcl()) return nil } // setupNodeDrainer creates a node drainer which will be enabled when a server // becomes a leader. func (s *Server) setupNodeDrainer() { // Create a shim around Raft requests shim := drainerShim{s} c := &drainer.NodeDrainerConfig{ Logger: s.logger, Raft: shim, JobFactory: drainer.GetDrainingJobWatcher, NodeFactory: drainer.GetNodeWatcherFactory(), DrainDeadlineFactory: drainer.GetDeadlineNotifier, StateQueriesPerSecond: drainer.LimitStateQueriesPerSecond, BatchUpdateInterval: drainer.BatchUpdateInterval, } s.nodeDrainer = drainer.NewNodeDrainer(c) } // setupConsul is used to setup Server specific consul components. func (s *Server) setupConsul(consulConfigEntries consul.ConfigAPI, consulACLs consul.ACLsAPI) { s.consulConfigEntries = NewConsulConfigsAPI(consulConfigEntries, s.logger) s.consulACLs = NewConsulACLsAPI(consulACLs, s.logger, s.purgeSITokenAccessors) } // setupVaultClient is used to set up the Vault API client. func (s *Server) setupVaultClient() error { delegate := s.entVaultDelegate() v, err := NewVaultClient(s.config.VaultConfig, s.logger, s.purgeVaultAccessors, delegate) if err != nil { return err } s.vault = v return nil } // setupRPC is used to setup the RPC listener func (s *Server) setupRPC(tlsWrap tlsutil.RegionWrapper) error { // Populate the static RPC server s.setupRpcServer(s.rpcServer, nil) // Setup streaming endpoints s.setupStreamingEndpoints(s.rpcServer) listener, err := s.createRPCListener() if err != nil { listener.Close() return err } if s.config.ClientRPCAdvertise != nil { s.clientRpcAdvertise = s.config.ClientRPCAdvertise } else { s.clientRpcAdvertise = s.rpcListener.Addr() } // Verify that we have a usable advertise address clientAddr, ok := s.clientRpcAdvertise.(*net.TCPAddr) if !ok { listener.Close() return fmt.Errorf("Client RPC advertise address is not a TCP Address: %v", clientAddr) } if clientAddr.IP.IsUnspecified() { listener.Close() return fmt.Errorf("Client RPC advertise address is not advertisable: %v", clientAddr) } if s.config.ServerRPCAdvertise != nil { s.serverRpcAdvertise = s.config.ServerRPCAdvertise } else { // Default to the Serf Advertise + RPC Port serfIP := s.config.SerfConfig.MemberlistConfig.AdvertiseAddr if serfIP == "" { serfIP = s.config.SerfConfig.MemberlistConfig.BindAddr } addr := net.JoinHostPort(serfIP, fmt.Sprintf("%d", clientAddr.Port)) resolved, err := net.ResolveTCPAddr("tcp", addr) if err != nil { return fmt.Errorf("Failed to resolve Server RPC advertise address: %v", err) } s.serverRpcAdvertise = resolved } // Verify that we have a usable advertise address serverAddr, ok := s.serverRpcAdvertise.(*net.TCPAddr) if !ok { return fmt.Errorf("Server RPC advertise address is not a TCP Address: %v", serverAddr) } if serverAddr.IP.IsUnspecified() { listener.Close() return fmt.Errorf("Server RPC advertise address is not advertisable: %v", serverAddr) } wrapper := tlsutil.RegionSpecificWrapper(s.config.Region, tlsWrap) s.raftLayer = NewRaftLayer(s.serverRpcAdvertise, wrapper) return nil } // setupStreamingEndpoints is used to populate an RPC server with streaming // endpoints. This only gets called at server startup. func (s *Server) setupStreamingEndpoints(server *rpc.Server) { // The endpoints are client RPCs and don't include a connection // context. They also need to be registered as streaming endpoints in their // register() methods. clientAllocs := NewClientAllocationsEndpoint(s) clientAllocs.register() fsEndpoint := NewFileSystemEndpoint(s) fsEndpoint.register() agentEndpoint := NewAgentEndpoint(s) agentEndpoint.register() // Event is a streaming-only endpoint so we don't want to register it as a // normal RPC eventEndpoint := NewEventEndpoint(s) eventEndpoint.register() // Operator takes a RPC context but also has a streaming RPC that needs to // be registered operatorEndpoint := NewOperatorEndpoint(s, nil) operatorEndpoint.register() } // setupRpcServer is used to populate an RPC server with endpoints. This gets // called at startup but also once for every new RPC connection so that RPC // handlers can have per-connection context. func (s *Server) setupRpcServer(server *rpc.Server, ctx *RPCContext) { // These endpoints are client RPCs and don't include a connection context _ = server.Register(NewClientStatsEndpoint(s)) _ = server.Register(newNodeMetaEndpoint(s)) // These endpoints have their streaming component registered in // setupStreamingEndpoints, but their non-streaming RPCs are registered // here. _ = server.Register(NewClientAllocationsEndpoint(s)) _ = server.Register(NewFileSystemEndpoint(s)) _ = server.Register(NewAgentEndpoint(s)) _ = server.Register(NewOperatorEndpoint(s, ctx)) // All other endpoints include the connection context and don't need to be // registered as streaming endpoints _ = server.Register(NewACLEndpoint(s, ctx)) _ = server.Register(NewAllocEndpoint(s, ctx)) _ = server.Register(NewClientCSIEndpoint(s, ctx)) _ = server.Register(NewCSIVolumeEndpoint(s, ctx)) _ = server.Register(NewCSIPluginEndpoint(s, ctx)) _ = server.Register(NewDeploymentEndpoint(s, ctx)) _ = server.Register(NewEvalEndpoint(s, ctx)) _ = server.Register(NewJobEndpoints(s, ctx)) _ = server.Register(NewKeyringEndpoint(s, ctx, s.encrypter)) _ = server.Register(NewNamespaceEndpoint(s, ctx)) _ = server.Register(NewNodeEndpoint(s, ctx)) _ = server.Register(NewNodePoolEndpoint(s, ctx)) _ = server.Register(NewPeriodicEndpoint(s, ctx)) _ = server.Register(NewPlanEndpoint(s, ctx)) _ = server.Register(NewRegionEndpoint(s, ctx)) _ = server.Register(NewScalingEndpoint(s, ctx)) _ = server.Register(NewSearchEndpoint(s, ctx)) _ = server.Register(NewServiceRegistrationEndpoint(s, ctx)) _ = server.Register(NewStatusEndpoint(s, ctx)) _ = server.Register(NewSystemEndpoint(s, ctx)) _ = server.Register(NewVariablesEndpoint(s, ctx, s.encrypter)) // Register non-streaming ent := NewEnterpriseEndpoints(s, ctx) ent.Register(server) } // setupRaft is used to setup and initialize Raft func (s *Server) setupRaft() error { // If we have an unclean exit then attempt to close the Raft store. defer func() { if s.raft == nil && s.raftStore != nil { if err := s.raftStore.Close(); err != nil { s.logger.Error("failed to close Raft store", "error", err) } } }() // Create the FSM fsmConfig := &FSMConfig{ EvalBroker: s.evalBroker, Periodic: s.periodicDispatcher, Blocked: s.blockedEvals, Logger: s.logger, Region: s.Region(), EnableEventBroker: s.config.EnableEventBroker, EventBufferSize: s.config.EventBufferSize, JobTrackedVersions: s.config.JobTrackedVersions, } var err error s.fsm, err = NewFSM(fsmConfig) if err != nil { return err } // Create a transport layer trans := raft.NewNetworkTransport(s.raftLayer, 3, s.config.RaftTimeout, s.config.LogOutput) s.raftTransport = trans // Make sure we set the Logger. s.config.RaftConfig.Logger = s.logger.Named("raft") s.config.RaftConfig.LogOutput = nil // Our version of Raft protocol 2 requires the LocalID to match the network // address of the transport. Raft protocol 3 uses permanent ids. s.config.RaftConfig.LocalID = raft.ServerID(trans.LocalAddr()) if s.config.RaftConfig.ProtocolVersion >= 3 { s.config.RaftConfig.LocalID = raft.ServerID(s.config.NodeID) } // Build an all in-memory setup for dev mode, otherwise prepare a full // disk-based setup. var log raft.LogStore var stable raft.StableStore var snap raft.SnapshotStore if s.config.DevMode { store := raft.NewInmemStore() s.raftInmem = store stable = store log = store snap = raft.NewDiscardSnapshotStore() } else { // Create the base raft path path := filepath.Join(s.config.DataDir, raftState) if err := ensurePath(path, true); err != nil { return err } // Check Raft version and update the version file. raftVersionFilePath := filepath.Join(path, "version") raftVersionFileContent := strconv.Itoa(int(s.config.RaftConfig.ProtocolVersion)) if err := s.checkRaftVersionFile(raftVersionFilePath); err != nil { return err } if err := os.WriteFile(raftVersionFilePath, []byte(raftVersionFileContent), 0644); err != nil { return fmt.Errorf("failed to write Raft version file: %v", err) } // Create the BoltDB backend, with NoFreelistSync option store, raftErr := raftboltdb.New(raftboltdb.Options{ Path: filepath.Join(path, "raft.db"), NoSync: false, // fsync each log write BoltOptions: &bbolt.Options{ NoFreelistSync: s.config.RaftBoltNoFreelistSync, }, }) if raftErr != nil { return raftErr } s.raftStore = store stable = store s.logger.Info("setting up raft bolt store", "no_freelist_sync", s.config.RaftBoltNoFreelistSync) // Start publishing bboltdb metrics go store.RunMetrics(s.shutdownCtx, 0) // Wrap the store in a LogCache to improve performance cacheStore, err := raft.NewLogCache(raftLogCacheSize, store) if err != nil { store.Close() return err } log = cacheStore // Create the snapshot store snapshots, err := raft.NewFileSnapshotStore(path, snapshotsRetained, s.config.LogOutput) if err != nil { if s.raftStore != nil { s.raftStore.Close() } return err } snap = snapshots // For an existing cluster being upgraded to the new version of // Raft, we almost never want to run recovery based on the old // peers.json file. We create a peers.info file with a helpful // note about where peers.json went, and use that as a sentinel // to avoid ingesting the old one that first time (if we have to // create the peers.info file because it's not there, we also // blow away any existing peers.json file). peersFile := filepath.Join(path, "peers.json") peersInfoFile := filepath.Join(path, "peers.info") if _, err := os.Stat(peersInfoFile); os.IsNotExist(err) { if err := os.WriteFile(peersInfoFile, []byte(peersInfoContent), 0644); err != nil { return fmt.Errorf("failed to write peers.info file: %v", err) } // Blow away the peers.json file if present, since the // peers.info sentinel wasn't there. if _, err := os.Stat(peersFile); err == nil { if err := os.Remove(peersFile); err != nil { return fmt.Errorf("failed to delete peers.json, please delete manually (see peers.info for details): %v", err) } s.logger.Info("deleted peers.json file (see peers.info for details)") } } else if _, err := os.Stat(peersFile); err == nil { s.logger.Info("found peers.json file, recovering Raft configuration...") var configuration raft.Configuration if s.config.RaftConfig.ProtocolVersion < 3 { configuration, err = raft.ReadPeersJSON(peersFile) } else { configuration, err = raft.ReadConfigJSON(peersFile) } if err != nil { return fmt.Errorf("recovery failed to parse peers.json: %v", err) } tmpFsm, err := NewFSM(fsmConfig) if err != nil { return fmt.Errorf("recovery failed to make temp FSM: %v", err) } if err := raft.RecoverCluster(s.config.RaftConfig, tmpFsm, log, stable, snap, trans, configuration); err != nil { return fmt.Errorf("recovery failed: %v", err) } if err := os.Remove(peersFile); err != nil { return fmt.Errorf("recovery failed to delete peers.json, please delete manually (see peers.info for details): %v", err) } s.logger.Info("deleted peers.json file after successful recovery") } } // If we are a single server cluster and the state is clean then we can // bootstrap now. if s.isSingleServerCluster() { hasState, err := raft.HasExistingState(log, stable, snap) if err != nil { return err } if !hasState { configuration := raft.Configuration{ Servers: []raft.Server{ { ID: s.config.RaftConfig.LocalID, Address: trans.LocalAddr(), }, }, } if err := raft.BootstrapCluster(s.config.RaftConfig, log, stable, snap, trans, configuration); err != nil { return err } } } // Setup the Raft store s.raft, err = raft.NewRaft(s.config.RaftConfig, s.fsm, log, stable, snap, trans) if err != nil { return err } return nil } // checkRaftVersionFile reads the Raft version file and returns an error if // the Raft version is incompatible with the current version configured. // Provide best-effort check if the file cannot be read. func (s *Server) checkRaftVersionFile(path string) error { raftVersion := s.config.RaftConfig.ProtocolVersion baseWarning := "use the 'nomad operator raft list-peers' command to make sure the Raft protocol versions are consistent" _, err := os.Stat(path) if err != nil { if os.IsNotExist(err) { return nil } s.logger.Warn(fmt.Sprintf("unable to read Raft version file, %s", baseWarning), "error", err) return nil } v, err := os.ReadFile(path) if err != nil { s.logger.Warn(fmt.Sprintf("unable to read Raft version file, %s", baseWarning), "error", err) return nil } previousVersion, err := strconv.Atoi(strings.TrimSpace(string(v))) if err != nil { s.logger.Warn(fmt.Sprintf("invalid Raft protocol version in Raft version file, %s", baseWarning), "error", err) return nil } if raft.ProtocolVersion(previousVersion) > raftVersion { return fmt.Errorf("downgrading Raft is not supported, current version is %d, previous version was %d", raftVersion, previousVersion) } return nil } // setupSerf is used to setup and initialize a Serf func (s *Server) setupSerf(conf *serf.Config, ch chan serf.Event, path string) (*serf.Serf, error) { conf.Init() conf.NodeName = fmt.Sprintf("%s.%s", s.config.NodeName, s.config.Region) conf.Tags["role"] = "nomad" conf.Tags["region"] = s.config.Region conf.Tags["dc"] = s.config.Datacenter conf.Tags["build"] = s.config.Build conf.Tags["revision"] = s.config.Revision conf.Tags["vsn"] = deprecatedAPIMajorVersionStr // for Nomad <= v1.2 compat conf.Tags["raft_vsn"] = fmt.Sprintf("%d", s.config.RaftConfig.ProtocolVersion) conf.Tags["id"] = s.config.NodeID conf.Tags["rpc_addr"] = s.clientRpcAdvertise.(*net.TCPAddr).IP.String() // Address that clients will use to RPC to servers conf.Tags["port"] = fmt.Sprintf("%d", s.serverRpcAdvertise.(*net.TCPAddr).Port) // Port servers use to RPC to one and another if s.isSingleServerCluster() { conf.Tags["bootstrap"] = "1" } bootstrapExpect := s.config.BootstrapExpect if bootstrapExpect != 0 { conf.Tags["expect"] = fmt.Sprintf("%d", bootstrapExpect) } if s.config.NonVoter { conf.Tags["nonvoter"] = "1" } if s.config.RedundancyZone != "" { conf.Tags[AutopilotRZTag] = s.config.RedundancyZone } if s.config.UpgradeVersion != "" { conf.Tags[AutopilotVersionTag] = s.config.UpgradeVersion } logger := s.logger.StandardLoggerIntercept(&log.StandardLoggerOptions{InferLevels: true}) conf.MemberlistConfig.Logger = logger conf.Logger = logger conf.MemberlistConfig.LogOutput = nil conf.LogOutput = nil conf.EventCh = ch if !s.config.DevMode { conf.SnapshotPath = filepath.Join(s.config.DataDir, path) if err := ensurePath(conf.SnapshotPath, false); err != nil { return nil, err } } // LeavePropagateDelay is used to make sure broadcasted leave intents propagate // This value was tuned using https://www.serf.io/docs/internals/simulator.html to // allow for convergence in 99.9% of nodes in a 10 node cluster conf.LeavePropagateDelay = 1 * time.Second conf.Merge = &serfMergeDelegate{} // Until Nomad supports this fully, we disable automatic resolution. // When enabled, the Serf gossip may just turn off if we are the minority // node which is rather unexpected. conf.EnableNameConflictResolution = false return serf.Create(conf) } // shouldReloadSchedulers checks the new config to determine if the scheduler worker pool // needs to be updated. If so, returns true and a pointer to a populated SchedulerWorkerPoolArgs func shouldReloadSchedulers(s *Server, newPoolArgs *SchedulerWorkerPoolArgs) (bool, *SchedulerWorkerPoolArgs) { s.workerConfigLock.RLock() defer s.workerConfigLock.RUnlock() newSchedulers := make([]string, len(newPoolArgs.EnabledSchedulers)) copy(newSchedulers, newPoolArgs.EnabledSchedulers) sort.Strings(newSchedulers) if s.config.NumSchedulers != newPoolArgs.NumSchedulers { return true, newPoolArgs } oldSchedulers := make([]string, len(s.config.EnabledSchedulers)) copy(oldSchedulers, s.config.EnabledSchedulers) sort.Strings(oldSchedulers) for i, v := range newSchedulers { if oldSchedulers[i] != v { return true, newPoolArgs } } return false, nil } // SchedulerWorkerPoolArgs are the two key configuration options for a Nomad server's // scheduler worker pool. Before using, you should always verify that they are rational // using IsValid() or IsInvalid() type SchedulerWorkerPoolArgs struct { NumSchedulers int EnabledSchedulers []string } // IsInvalid returns true when the SchedulerWorkerPoolArgs.IsValid is false func (swpa SchedulerWorkerPoolArgs) IsInvalid() bool { return !swpa.IsValid() } // IsValid verifies that the pool arguments are valid. That is, they have a non-negative // numSchedulers value and the enabledSchedulers list has _core and only refers to known // schedulers. func (swpa SchedulerWorkerPoolArgs) IsValid() bool { if swpa.NumSchedulers < 0 { // the pool has to be non-negative return false } // validate the scheduler list against the builtin types and _core foundCore := false for _, sched := range swpa.EnabledSchedulers { if sched == structs.JobTypeCore { foundCore = true continue // core is not in the BuiltinSchedulers map, so we need to skip that check } if _, ok := scheduler.BuiltinSchedulers[sched]; !ok { return false // found an unknown scheduler in the list; bailing out } } return foundCore } // Copy returns a clone of a SchedulerWorkerPoolArgs struct. Concurrent access // concerns should be managed by the caller. func (swpa SchedulerWorkerPoolArgs) Copy() SchedulerWorkerPoolArgs { out := SchedulerWorkerPoolArgs{ NumSchedulers: swpa.NumSchedulers, EnabledSchedulers: make([]string, len(swpa.EnabledSchedulers)), } copy(out.EnabledSchedulers, swpa.EnabledSchedulers) return out } func getSchedulerWorkerPoolArgsFromConfigLocked(c *Config) *SchedulerWorkerPoolArgs { return &SchedulerWorkerPoolArgs{ NumSchedulers: c.NumSchedulers, EnabledSchedulers: c.EnabledSchedulers, } } // GetSchedulerWorkerInfo returns a slice of WorkerInfos from all of // the running scheduler workers. func (s *Server) GetSchedulerWorkersInfo() []WorkerInfo { s.workerLock.RLock() defer s.workerLock.RUnlock() out := make([]WorkerInfo, len(s.workers)) for i := 0; i < len(s.workers); i = i + 1 { workerInfo := s.workers[i].Info() out[i] = workerInfo.Copy() } return out } // GetSchedulerWorkerConfig returns a clean copy of the server's current scheduler // worker config. func (s *Server) GetSchedulerWorkerConfig() SchedulerWorkerPoolArgs { s.workerConfigLock.RLock() defer s.workerConfigLock.RUnlock() return getSchedulerWorkerPoolArgsFromConfigLocked(s.config).Copy() } func (s *Server) SetSchedulerWorkerConfig(newArgs SchedulerWorkerPoolArgs) SchedulerWorkerPoolArgs { if reload, newVals := shouldReloadSchedulers(s, &newArgs); reload { if newVals.IsValid() { reloadSchedulers(s, newVals) } } return s.GetSchedulerWorkerConfig() } // reloadSchedulers validates the passed scheduler worker pool arguments, locks the // workerLock, applies the new values to the s.config, and restarts the pool func reloadSchedulers(s *Server, newArgs *SchedulerWorkerPoolArgs) { if newArgs == nil || newArgs.IsInvalid() { s.logger.Info("received invalid arguments for scheduler pool reload; ignoring") return } // reload will modify the server.config so it needs a write lock s.workerConfigLock.Lock() defer s.workerConfigLock.Unlock() // reload modifies the worker slice so it needs a write lock s.workerLock.Lock() defer s.workerLock.Unlock() // TODO: If EnabledSchedulers didn't change, we can scale rather than drain and rebuild s.config.NumSchedulers = newArgs.NumSchedulers s.config.EnabledSchedulers = newArgs.EnabledSchedulers s.setupNewWorkersLocked() } // setupWorkers is used to start the scheduling workers func (s *Server) setupWorkers(ctx context.Context) error { poolArgs := s.GetSchedulerWorkerConfig() go s.listenWorkerEvents() // we will be writing to the worker slice s.workerLock.Lock() defer s.workerLock.Unlock() return s.setupWorkersLocked(ctx, poolArgs) } // setupWorkersLocked directly manipulates the server.config, so it is not safe to // call concurrently. Use setupWorkers() or call this with server.workerLock set. func (s *Server) setupWorkersLocked(ctx context.Context, poolArgs SchedulerWorkerPoolArgs) error { // Check if all the schedulers are disabled if len(poolArgs.EnabledSchedulers) == 0 || poolArgs.NumSchedulers == 0 { s.logger.Warn("no enabled schedulers") return nil } // Check if the core scheduler is not enabled foundCore := false for _, sched := range poolArgs.EnabledSchedulers { if sched == structs.JobTypeCore { foundCore = true continue } if _, ok := scheduler.BuiltinSchedulers[sched]; !ok { return fmt.Errorf("invalid configuration: unknown scheduler %q in enabled schedulers", sched) } } if !foundCore { return fmt.Errorf("invalid configuration: %q scheduler not enabled", structs.JobTypeCore) } s.logger.Info("starting scheduling worker(s)", "num_workers", poolArgs.NumSchedulers, "schedulers", poolArgs.EnabledSchedulers) // Start the workers for i := 0; i < s.config.NumSchedulers; i++ { if w, err := NewWorker(ctx, s, poolArgs); err != nil { return err } else { s.logger.Debug("started scheduling worker", "id", w.ID(), "index", i+1, "of", s.config.NumSchedulers) s.workers = append(s.workers, w) } } s.logger.Info("started scheduling worker(s)", "num_workers", s.config.NumSchedulers, "schedulers", s.config.EnabledSchedulers) return nil } // setupNewWorkersLocked directly manipulates the server.config, so it is not safe to // call concurrently. Use reloadWorkers() or call this with server.workerLock set. func (s *Server) setupNewWorkersLocked() error { // make a copy of the s.workers array so we can safely stop those goroutines asynchronously oldWorkers := make([]*Worker, len(s.workers)) defer s.stopOldWorkers(oldWorkers) copy(oldWorkers, s.workers) s.logger.Info(fmt.Sprintf("marking %v current schedulers for shutdown", len(oldWorkers))) // build a clean backing array and call setupWorkersLocked like setupWorkers // does in the normal startup path s.workers = make([]*Worker, 0, s.config.NumSchedulers) poolArgs := getSchedulerWorkerPoolArgsFromConfigLocked(s.config).Copy() err := s.setupWorkersLocked(s.shutdownCtx, poolArgs) if err != nil { return err } // if we're the leader, we need to pause all of the pausable workers. s.handlePausableWorkers(s.IsLeader()) return nil } // stopOldWorkers is called once setupNewWorkers has created the new worker // array to asynchronously stop each of the old workers individually. func (s *Server) stopOldWorkers(oldWorkers []*Worker) { workerCount := len(oldWorkers) for i, w := range oldWorkers { s.logger.Debug("stopping old scheduling worker", "id", w.ID(), "index", i+1, "of", workerCount) go w.Stop() } } // listenWorkerEvents listens for events emitted by scheduler workers and log // them if necessary. Some events may be skipped to avoid polluting logs with // duplicates. func (s *Server) listenWorkerEvents() { loggedAt := make(map[string]time.Time) gcDeadline := 4 * time.Hour gcTicker := time.NewTicker(10 * time.Second) defer gcTicker.Stop() for { select { case <-gcTicker.C: for k, v := range loggedAt { if time.Since(v) >= gcDeadline { delete(loggedAt, k) } } case e := <-s.workersEventCh: switch event := e.(type) { case *scheduler.PortCollisionEvent: if event == nil || event.Node == nil { continue } if _, ok := loggedAt[event.Node.ID]; ok { continue } eventJson, err := json.Marshal(event.Sanitize()) if err != nil { s.logger.Debug("failed to encode event to JSON", "error", err) } s.logger.Warn("unexpected node port collision, refer to https://www.nomadproject.io/s/port-plan-failure for more information", "node_id", event.Node.ID, "reason", event.Reason, "event", string(eventJson)) loggedAt[event.Node.ID] = time.Now() } case <-s.shutdownCh: return } } } // numPeers is used to check on the number of known peers, including the local // node. func (s *Server) numPeers() (int, error) { future := s.raft.GetConfiguration() if err := future.Error(); err != nil { return 0, err } configuration := future.Configuration() return len(configuration.Servers), nil } // IsLeader checks if this server is the cluster leader func (s *Server) IsLeader() bool { return s.raft.State() == raft.Leader } // Join is used to have Nomad join the gossip ring // The target address should be another node listening on the // Serf address func (s *Server) Join(addrs []string) (int, error) { return s.serf.Join(addrs, true) } // LocalMember is used to return the local node func (s *Server) LocalMember() serf.Member { return s.serf.LocalMember() } // Members is used to return the members of the serf cluster func (s *Server) Members() []serf.Member { return s.serf.Members() } // RemoveFailedNode is used to remove a failed node from the cluster func (s *Server) RemoveFailedNode(node string) error { return s.serf.RemoveFailedNode(node) } // KeyManager returns the Serf keyring manager func (s *Server) KeyManager() *serf.KeyManager { return s.serf.KeyManager() } // Encrypted determines if gossip is encrypted func (s *Server) Encrypted() bool { return s.serf.EncryptionEnabled() } // State returns the underlying state store. This should *not* // be used to modify state directly. func (s *Server) State() *state.StateStore { return s.fsm.State() } // setLeaderAcl stores the given ACL token as the current leader's ACL token. func (s *Server) setLeaderAcl(token string) { s.leaderAclLock.Lock() s.leaderAcl = token s.leaderAclLock.Unlock() } // getLeaderAcl retrieves the leader's ACL token func (s *Server) getLeaderAcl() string { s.leaderAclLock.Lock() defer s.leaderAclLock.Unlock() return s.leaderAcl } // Atomically sets a readiness state flag when leadership is obtained, to indicate that server is past its barrier write func (s *Server) setConsistentReadReady() { s.readyForConsistentReads.Store(true) } // Atomically reset readiness state flag on leadership revoke func (s *Server) resetConsistentReadReady() { s.readyForConsistentReads.Store(false) } // Returns true if this server is ready to serve consistent reads func (s *Server) isReadyForConsistentReads() bool { return s.readyForConsistentReads.Load() } // Regions returns the known regions in the cluster. func (s *Server) Regions() []string { s.peerLock.RLock() defer s.peerLock.RUnlock() regions := make([]string, 0, len(s.peers)) for region := range s.peers { regions = append(regions, region) } sort.Strings(regions) return regions } // RPC is used to make a local RPC call func (s *Server) RPC(method string, args interface{}, reply interface{}) error { codec := &codec.InmemCodec{ Method: method, Args: args, Reply: reply, } if err := s.rpcServer.ServeRequest(codec); err != nil { return err } return codec.Err } // StreamingRpcHandler is used to make a streaming RPC call. func (s *Server) StreamingRpcHandler(method string) (structs.StreamingRpcHandler, error) { return s.streamingRpcs.GetHandler(method) } // Stats is used to return statistics for debugging and insight // for various sub-systems func (s *Server) Stats() map[string]map[string]string { toString := func(v uint64) string { return strconv.FormatUint(v, 10) } stats := map[string]map[string]string{ "nomad": { "server": "true", "leader": fmt.Sprintf("%v", s.IsLeader()), "leader_addr": string(s.raft.Leader()), "bootstrap": fmt.Sprintf("%v", s.isSingleServerCluster()), "known_regions": toString(uint64(len(s.peers))), }, "raft": s.raft.Stats(), "serf": s.serf.Stats(), "runtime": stats.RuntimeStats(), "vault": s.vault.Stats(), } return stats } // EmitRaftStats is used to export metrics about raft indexes and state store snapshot index func (s *Server) EmitRaftStats(period time.Duration, stopCh <-chan struct{}) { timer, stop := helper.NewSafeTimer(period) defer stop() for { timer.Reset(period) select { case <-timer.C: lastIndex := s.raft.LastIndex() metrics.SetGauge([]string{"raft", "lastIndex"}, float32(lastIndex)) appliedIndex := s.raft.AppliedIndex() metrics.SetGauge([]string{"raft", "appliedIndex"}, float32(appliedIndex)) stateStoreSnapshotIndex, err := s.State().LatestIndex() if err != nil { s.logger.Warn("Unable to read snapshot index from statestore, metric will not be emitted", "error", err) } else { metrics.SetGauge([]string{"state", "snapshotIndex"}, float32(stateStoreSnapshotIndex)) } case <-stopCh: return } } } // setReplyQueryMeta is an RPC helper function to properly populate the query // meta for a read response. It populates the index using a floored value // obtained from the index table as well as leader and last contact // information. // // If the passed state.StateStore is nil, a new handle is obtained. func (s *Server) setReplyQueryMeta(stateStore *state.StateStore, table string, reply *structs.QueryMeta) error { // Protect against an empty stateStore object to avoid panic. if stateStore == nil { stateStore = s.fsm.State() } // Get the index from the index table and ensure the value is floored to at // least one. index, err := stateStore.Index(table) if err != nil { return err } reply.Index = helper.Max(1, index) // Set the query response. s.setQueryMeta(reply) return nil } // Region returns the region of the server func (s *Server) Region() string { return s.config.Region } // Datacenter returns the data center of the server func (s *Server) Datacenter() string { return s.config.Datacenter } // GetConfig returns the config of the server for testing purposes only func (s *Server) GetConfig() *Config { return s.config } // ReplicationToken returns the token used for replication. We use a method to support // dynamic reloading of this value later. func (s *Server) ReplicationToken() string { return s.config.ReplicationToken } // ClusterID returns the unique ID for this cluster. // // Any Nomad server agent may call this method to get at the ID. // If we are the leader and the ID has not yet been created, it will // be created now. Otherwise an error is returned. // // The ID will not be created until all participating servers have reached // a minimum version (0.10.4). func (s *Server) ClusterID() (string, error) { s.clusterIDLock.Lock() defer s.clusterIDLock.Unlock() // try to load the cluster ID from state store fsmState := s.fsm.State() existingMeta, err := fsmState.ClusterMetadata(nil) if err != nil { s.logger.Named("core").Error("failed to get cluster ID", "error", err) return "", err } // got the cluster ID from state store, cache that and return it if existingMeta != nil && existingMeta.ClusterID != "" { return existingMeta.ClusterID, nil } // if we are not the leader, nothing more we can do if !s.IsLeader() { return "", errors.New("cluster ID not ready yet") } // we are the leader, try to generate the ID now generatedID, err := s.generateClusterID() if err != nil { return "", err } return generatedID, nil } func (s *Server) isSingleServerCluster() bool { return s.config.BootstrapExpect == 1 } // peersInfoContent is used to help operators understand what happened to the // peers.json file. This is written to a file called peers.info in the same // location. const peersInfoContent = ` As of Nomad 0.5.5, the peers.json file is only used for recovery after an outage. The format of this file depends on what the server has configured for its Raft protocol version. Please see the server configuration page at https://www.nomadproject.io/docs/configuration/server#raft_protocol for more details about this parameter. For Raft protocol version 2 and earlier, this should be formatted as a JSON array containing the address and port of each Nomad server in the cluster, like this: [ "10.1.0.1:4647", "10.1.0.2:4647", "10.1.0.3:4647" ] For Raft protocol version 3 and later, this should be formatted as a JSON array containing the node ID, address:port, and suffrage information of each Nomad server in the cluster, like this: [ { "id": "adf4238a-882b-9ddc-4a9d-5b6758e4159e", "address": "10.1.0.1:4647", "non_voter": false }, { "id": "8b6dda82-3103-11e7-93ae-92361f002671", "address": "10.1.0.2:4647", "non_voter": false }, { "id": "97e17742-3103-11e7-93ae-92361f002671", "address": "10.1.0.3:4647", "non_voter": false } ] The "id" field is the node ID of the server. This can be found in the logs when the server starts up, or in the "node-id" file inside the server's data directory. The "address" field is the address and port of the server. The "non_voter" field controls whether the server is a non-voter, which is used in some advanced Autopilot configurations, please see https://www.nomadproject.io/guides/operations/outage.html for more information. If "non_voter" is omitted it will default to false, which is typical for most clusters. Under normal operation, the peers.json file will not be present. When Nomad starts for the first time, it will create this peers.info file and delete any existing peers.json file so that recovery doesn't occur on the first startup. Once this peers.info file is present, any peers.json file will be ingested at startup, and will set the Raft peer configuration manually to recover from an outage. It's crucial that all servers in the cluster are shut down before creating the peers.json file, and that all servers receive the same configuration. Once the peers.json file is successfully ingested and applied, it will be deleted. Please see https://www.nomadproject.io/guides/outage.html for more information. `